Telemetering and tabulating timer



M 1940' R. w. BUMSTEAD TELEMETERING AND TABULATING TIMER 5 Sheets-Sheet l I NVEN TOR kwwqww Filed July 6, 1934 y 165'1940- R. w. BUMSTEAD 2,207,715

TELEMETERING AND TABULATING TIMER Filed July 6, 1934 5 Sheets-Sheet 2 I N VEN TOR g @MWWQ July 16, 1940.

R. W. BUMSTEAD TELEMETERI NG AND 'L'LABULATING TIMER 5 Sheets-Sheet 3 Filed July 6, 1934 4 kkukhwm aetk m .m "h nmoiuq 2543 56 mutmwmeziuwt to mxsmt BREQZQMQ Eotk y 16, 1949' R. w. BUMSTEAD TELEMETERING AND TABULATING TIMER Filed July 6, 1934 5 Sheets-Sheet 4 INVFNTOR.

7 1940' k. w. BUMQSTEAD 2,207,715

TELEMETERING AND TABULATING TIMER Filed July 6, 1934 5 Sheets-Sheet 5 WARP FILLING KNOCK-OFF I37 STOP-MOTION STOP-MOTION CONTROL snurne m8 WARP LOOM INVENTOR.

Patented July 16, 1940 UNITED STATES PATENT OFFICE 24 Claims.

This invention relates to telemetering and tabulating timers and has particular reference to systems for monitoring the operation of productive machinery in an industrial plant, also for g; determining and tabulating in condensed form the extent and causes of machine idleness.

In my U. S. Patent No. 1,739,058, granted December 10, 1929. and entitled Elapsed-runningtime counter, I disclosed a device for registering in the summation of running-time intervals of any number of machines in a group. The direct measurement of idle time was not suggested. No

means were shown for obtaining a quantitative analysis of idle time, classified as to causes, nor lid for simultaneously tabulating the elapsed time in respect to machine groups of the operator's sets and in respect to machine groups classified by kinds of product thereof,or according to any other basis of classification. The present invention, therefore, contemplates making provision for the attainment of these objects.

The science of industrial management clearly points out the advantages to be derived from a close observance of operating conditions in re- 25 spect to mass production. Where the number of machine units is large, the cost of fact-finding for better control of the operations becomes a serious consideration. Many of the wastes in industry have been tolerated'in the past, in some cases, because the cost of personal supervision of all the productive units in the plant seemed to out-weigh the savings to be made, and, in other cases, because no basis was available for fixing the responsibility for certain inefl'lciencies 3 upon the proper individuals. As a consequence, a lack of co-ordination of efforts of the various workers has at times been manifested, even where it was to the interest of the workers themselves, as well as of the plant owners, that ma- 40 chine idleness be minimized and the rate of production be increased. Under these conditions it is apparent that a machine operator should not be blamed for delays in production assignable to others, as when one or more of his machines are in need of repairs, or when he waits for raw material, and for his finished work to be inspected and removed. The proper indiyiduals to be penalized in such cases are they who failed to do their part. There, again the responsibility may not be, theirs, if no notice was given that certain particular machines were in need of their attention.

The difliculties Just now recounted are of such proportions in many a plant that automatic and continuous monitoring of all the productive machinery therein is fully warranted, even though the cost and maintenance of the monitoring equipment were found to be considerable.- Depending, of course, upon how much room for improvement existed in a particular plant, the tan- 5 gible savingsto be made would usually stand out in conspicuous comparison with the capital invested in-the monitoring installation. The improved performance of the productive units and the improved morale of looked upon as a fair return from such invested capital.

My invention in its broad aspects has been discussed in the foregoing preamble. More speciflcally, it is among the objects of my inven- :15 tion to provide monitoring, signalling, telemetering and tabulating apparatus at least partially under control of a plurality of productive ma-' chines in respect to the operation and idleness of which it is desired to accumulate elapsed time 2 registrations.

Another object of my invention isto provide apparatus including a plurality of electrically controlled timing registers conveniently arranged in an instrument panel, and remote control 25 means therefor, located at each of a plurality of machines that are to be continuously monitored during periods of plant operation, the apparatus serving as a system for quantitative analysis and tabulation of results of the operation of the ma- 30 chines with which it is connected.

Another object of my invention is to provide a supervisory control system for aiding an operative who tends a plurality of machines-to keep the maximum number of them in operation at all 5 times.

Another object of my invention is to provide a .Work-and-idleness meter by which a factory supervisor may be kept informed as to the progress of work in his department, and especially 40 that he may be apprised as to the occurrence of conditions which tend to handicap the operatives, so that he may immediately take steps to remedy the matter.

Another object of my invention is to provide a 5 means for determining the relative extent of machine stoppage for various causes.

Another object of my invention is to provide means for tabulating elapsed running-time meas- 'urements in respect to various groups of produc- 50 tive machines.

Another object of my invention is to provide a call system for promptly notifying a fixer when repairs are needed in respect to any one or more machines in his section. 55

the operatives should be "10 a Another object of my invention is to provide a system for giving notice'oi miscellaneous requirements for increasing production, thereby to minimize the time of waiting for raw material, 1

for repair material, and for the inspection and removal of finished goods.

' The foregoing and other objects and advantages of my invention are attained by the tion, reference being bad to the accompanying .impulses to my monitoring system; and

drawings in which Fig. 1 is a side elevation view of two of the clawed time registers and their actuating de- 'vices;

Fig. 2 is a front view of one of the registers;

Fig. 3 and Fig. 4 when joined thereto, end'to end, constitute a schematic wiring diagram of one embodiment of my invention;

Fig. 5 shows modifications of the wiring diagram to meet certain occasional requirements;

Fig. 6 shows further modifications, particularly with respect to the wiring connections for one of the rotary switches which I prefer to use.

Fig. 7 is a perspective view of a transmitter, or signal box adapted to be attached to a machine (and to be at least partially controlled thereby) for remotely controlling my telemetering system;

Fig. 8 is a cross-sectional view of the transmitter otherwise shown in Fig. 7;

Figs. 9 and 10 show each a difierent embodiment of manually operated switch, forming part of the transmitter;

Fig. 11 shows schematically a loom to which there is attached the various components of signalling apparatus suitable for transmitting Fig. 12 shows a modified application of my invention for purposes of recording the signals which may be transmitted from difierent productive units in response to the occurrence of different operating or idleness conditions.

Before describing in detail the various parts of my timing system, it may be well to observe generally that, as shown in Figs. 3 and 4, the system comprehends a number of signalling stations S, each individually associated with a machine whose operation is to be monitored. Like circuit connections exist within each of the signal boxes, hence they have been shown in station S10 as typical. The signal box in its structural details is best shown in Figs. 7, 8 and 9.

In the lower portion of Fig. 3, I show conven-.

tionally a number of timing registers assembled into a meter-panel. structurally each register may be of one or the other of the two types shown in Figs. 1 and 2. Each register is under the joint control of its own actuating magnet i2 and of a mechanical timing motion common to all the registers. This motion is periodic and is preferabiy driven by a motor through a time-controlled over one tooth of the ratchet wheel 20.

aao'rgiie tuating selected ones of the group registers and for tabulating the results of the elapsed time measurements according to difierent classifications. The cord-and-plug connections may be such that when the work on the machines is changed, or when the operator groups are rearranged, the new groupings of the machines may be properly reflected in the tabulative registrations of elapsed running time, etc.

In Fig. l I show two timing registers ii and 2! which, as counters, are similar in every respect, although their electro-magnetic actuating, mechanisms differ slightly according to the manner in which they are controlled. While these registers are essentially similar to those shown and described in my aforesaid patent, I have herein disclosed certain improvements of design in the control mechanisms. The upper timing register it is best adapted to make idle time accumulations, or else it may have assigned to it a 100% machine hour timing function. The lower timing register 2i is of the type preferred for measuring machine running time.

The register control mechanisms may be released by their respective magnets l? or 22. The registers ii and 21 are not advanced, however, until their controlv mechanisms are restored to normal by one of the periodic excursions of a clock-controlled driving mechanism presently to be described.

The escapement lever It has an opening it in which there is one tooth i5 for engagement with a dog It on the end of the armature arm H which is actuated by the magnet i2. The escapement member i3 is pivoted at l8 and carries the pawl is which is pivoted on the lever H at (it. The pawl i9 engages with a ratchet wheel and a spring 28 urges the pawl i9 against the toothed periphery of the ratchet wheel. The spring 28 also serves to retract the escapement lever i3 when disengaged by the uplifting of the armature ii, aswhen an impulse energizes the magnet I2. The escapement lever l3 may then be fully retracted and cause the pawl 19 to ride This ratchet wheel is restrained by the spring 29 from turning clockwise when the pawl i9 is being retracted. A driving gear is mounted on the same spindle with the ratchet wheel 20 and turns with it. The driven gear 25 meshes with gear 26 and transmits its motion either directly or through a'further gear train (not shown) to the drum dials 26, as illustrated in Fig. 2.

The armature H, when released by its magnet it, may be caused to drop by gravity, and this motion may, if desired, be accelerated by a spring is? bearing against a heel portion I88 of the ar mature W.

A time-controlled driving mechanism common to all the registers is in part and conventionally shown in Fig. 4. A clock 21 of any desired type has embodied therein a suitable impulsing device and preferably also a program device for starting up and stopping the operation of the entire monitoring system.

The program device is conventionally shown as including the battery 3! and the three circuits 32, 33, and 3i.' The circuit 32 leads to an onand-off relay 35 by which the motor 36 is started be permitted. However, when the magnet 31 is energized at the moment of changing shifts all of these circuits are broken and other circuits leading to the timing registers Ha, Ha, 2|: and the like will become operable during the night shift.

If the factory operates on three shifts, it would be a simple expedient to provide a separate group of operators registers for each shift and to arrange that the program device in the clock 21 would selectively close each of three multipolesingle-throw switches in place of the doublethrow switch operated by magnets 3'! and 38.

During mill hours the clock 21 is caused to send out periodic impulses on circuit 42 at a suitable rate for starting each cycle of operations to be performed by the motor 36. The clutch mechanism for engaging the motor 36 with its load is as follows: Periodic impulses are fed from the battery 38 through the clock impulsing device (not shown because conventional) through conductor 42 to the magnet 63 and thence to ground. Armature 44 engages with a member 45 which is supported by the pivot stud 48, the latter passing through an elongated hole so as to permit of a slight longitudinal movement oi the member 45. Upon the energization of magnet 43, its armature is caused to longitudinally shift the lever arm 45 against a tension of the spring 41, thereby to drive the roller 48 against a steep walled depression in the periphery of the cam 49. This cam is fixed to the shaft 50. The shaft is, therefore, turned through a slight angle, in a clockwise direction, thus urging a tooth 5| oi the worm wheel 52 into mesh with the worm 53. The motor 36 drives the worm continuously but the worm wheel 52, having a cut-away sector, is held out of mesh until the aforesaid starting movement takes place.

The motor 36 then carries the worm wheel BI and a number of cams fixedly mounted on the shaft through one complete revolution. In this manner various operations are cyclically performed in proper sequence for actuating my entire timing system. One of these operations, namely the stepping forward of selected registers whose control mechanisms have been released is accomplished by the cam 54 with which a lever arm 55 pivoted at 56 and having a roller 51- for engagement with said cam, is caused to convey a downward movement to the device for driving the registers and re-setting their control mechanisms. The roller 51 is urged against the cam 54 by the tension of a spring 58. A connecting link 59 communicates the motion of the lever arm 55 to a register driving member or frame 60 depression 62. By such lowering movement the cross bars 8| come into engagement with the detents 63' which are integral with the, escapement lever members I3 and 23.

Such escapement lever members therefore, as have been released by the operation of their associated armatures I! will be restored to the normal position. In the drawings, member 23 is shown as having been released while member 13 is shown as having been restored. This restoring movement is timed to take place after the magnets l2 and/or 22 have been de-energized.

Hence, the armature H will fall back into the recess behind the tooth i5 and the forward movement of the escapement lever l3 will have caused the pawl l9 to rotate the ratchet wheel 20 through an angle subtended by one tooth.

As will presently be shown in describing the circuit arrangements of this invention, means are provided whereby the control magnet for any particular register is connected to the signalling stations of different machines successively and to each such signalling station periodically. The impulses which are caused to actuate the register actuating magnets are, therefore, derived from only one signalling station at a time. The accumulative effect of such impulsing is, however, to integrate the elapsed time intertenths of hours, or in any other units, then the intermittent movement of the ratchet wheel 28 will effect the proper advancement of the dials 26, for that purpose. If, for example, register I i is allotted to the function of maintaining an idle time accumulation with respect to thirty machines, the idleness of one machine for thirty minutes will advance the counter just as much as would the idleness of all machines for one minute. In either case there would be a half hour of machine idleness to be registered or recorded. Assuming that each of the thirty machines can be monitored once every minute, then the magnet i2 may be adapted to pull up its armature l! a maximum of thirty times per minute, or .once each minute for each machine. Each release of the escapement lever i3 will then cause the advancement of the register dial 26 to register one minute of elapsed time, which'would be of the arc subtended by one figure on the drum of the lowest order, since the figures of that drum represent tenths of hours, or 6-minute periods.

Within reasonable limits, the actual machine running time may be accumulated on a register 2| with respect toany number of machines. The actuating mechanism for this register, as previously intimated, differs from that of the register II in that its escapement lever is provided with an orifice having three teeth, two in the lower jaw and one in the upper. The purpose of this arrangement is to prevent the full retraction of the pawl l9 over one tooth of the ratchet wheel 20 until the second of an indeterminate number of impulses for energizing the magnet within one of the periodic timing cycles has be n received. My aforesaid patent discloses the advantage of actuating a running-time register upon reception of the second impulse.

The impulses impressed upon the magnet 22 according to the present system, as well as in the system of my prior patent, are derived from a make-and-break device connected with each machine. It is necessary to difi'erentiate between a running machine and one which might be stopped with its 'make-and-break device in the make position. Since the first impulse-is meaningless by itself, and since there would be no object in has been shown .with the actuating lever 23 in the position it would occupy when the magnet has been energized for the second time within one timing cycle. The armature ii is shown attracted to the magnet 22. This means that the detent on the end thereof has permitted the escapement of each of the three teeth and is now ready to drop back, upon the cessation of the second impulse. The lever 23 has, therefore, reached its limiting position, as shown, by three steps, one of which was taken when the magnet E2 was energized for the first time, the second step when it was released, and the third step when it was energized for the second time.

If, during a timing cycle, the magnet 22 is energized and released only once, the partial retraction of the escapement lever 23 would beinsufilcient for the pawl it to ride over a tooth of the ratchet wheel 2@. Hence no advancement of the register would be possible in this case. The restoring movement of the cross bar 6! would merely re-set the escapement lever and restore the pawl i 9 to its original position without movement of the ratchet wheel 26'. The single impulse for partial retraction of the escapement lever arm would, therefore, be just as ineffective as though no impulse had been received.

It can readily be provided that the periodicity of the impulses applied to the magnet 22 will bear such a relation to'the timing cycle that there will never be less than two such impulses received during the time that the magnet 22 is connected with the make-and-brcak device of a given running machine. Hence, the advancement of the register will be such as to correctly indicate the.

elapsed running time of the machine to which it is connected.

Referring now to Figs. 3'and 4, I have shown certain switching means by which signals may be initiated successively and in rotation from each of the transmitting stations S, and thence directed through suitable channels for controlling the timing registers selectively. The embodiment illustrated includes three similar rotary switches, R1, R2, and R3, each switch having four banks of. contact segments. The rotary contact members or wipers of the four banks are to be understood as mounted upon one shaft 65 of each switch. Such wipers are rotated as a unit by means of a magnetic driving mechanism, operated step-bystep. Switches of this type are commonly used in automatic telephone exchanges and the details of their construction form no part of the present invention. In accordance with my invention, however, it is possible to use switches of this type, first for connecting the battery B with each of the transmitting stations S successively, and while so doing, to distribute the running time signals as transmitted from the several stations to the timingregisters selectively in accordance with any desired statistical classification of elapsed time integrations. Thus, from the upper level of the switches, running-time signals transmitted over the conductor a may be distributed say in accordance with the grouping of. machines under an operator" classification, so that if, for example, an operator tends four machines, the

signals from the four stations S1, S2,- S3, and 54 a single running- Fig. 4. As therein shown, there is a jack $6 suitable for a single conductor plug 6?. 66 may be identified with its respective machine transmitter S1, S2, etc. to which it will be connected periodically through an appropriate segment 68 in the upper bank of one of the rotary switches.

The manual switchboard also includes jacks 89 each suitable for a twin-conductor cord and plug ill. I have here represented a plug for one of these cords as having a sleeve connecting with the body of the jack 69, which in turn is wired to one of the segments H on the banks second ,rrom the tops of the rotary switches. The wipers for the first and second banks are connectedin parallel and hence receive the same signals. This two-way distribution of signals is made in order that the machine running-time be integrated in accordance with two different classifications or groupings of the machines. The tip of the plug 10, connects with the jack spring '52. Each of the latter is wired to its respective segment I 3 on the third banks of the rotary switches. The wiper for the third bank is fed with current from the battery B and hence a periodic distribution of impulses is made to the respective cord tips. The purpose of. making this periodic distribution of single impulses along with the reception of run-. hing-time signals is to provide a comparison between a 100% registration of machine hours for a predetermined group of machines (comprehending any desired number thereof) and, on

the other hand, a registration of actual running of register magnets U and 22 I have indicated a forked twin-conductor cord it having a plug it) at each of its branch terminals and a plug ta at its trunk terminal. The cord it may, for example, convey impulses from tip to tip and through jack I82 to magnet l2; for integrating the 100% machine hours in respect to machines of stations S1 and S1. The same cord 1d conveys running-time signals from stations S1 and S1 through the sleeves of its plugs l9 and it: to magnet 22g. The machines to which stations S1 and S7 are connected may be assumed to be producing style X.

Style Y may be the product of. certain machines with which stations S2, S5, S and S10 are.associated. Then cord it having four branches may be used to properly connect the magnets i211 and 221. each to its respective signaling channel or group of channels.

I have shown illustratively. certain concentrations of signaling circuits suitable for tabulation of the machine running-time by operators sets. One group comprises jacks 66 for stations S1, S2 and $5 from which the forked single-conductor cord. I83 establishes connection with jack 886 Each jack commutator.

for day-shift register He, also for night-shift register 2h. The other group comprises jacks for stations S6, S1 and S10 from which the forked to respond to signals from the stations of eachoperators group during his respective shift.

The concentration-of circuits between a multiplicity of jacks 69 and one register jack I82 may be facilitated by the use of intermediate jacks (not shown) having corresponding terminals interconnected. Thus, several cords 14 may have their trunk-end terminals connected in parallel. A simple cord-and-plug connection may then be made between one of the interconnected intermediate jacks and a register jack I82. Other concentration facilities may also suggest themselves to those skilled in the switchboard art.

Referring to Fig. 7, which is a perspective view of a preferred embodiment of my signal transmitting device S, I have ,provided a commutator switch or circuit interrupter mounted on a shaft 18 which is connected to an operative machine in any suitable manner; The machine itself does not appear in this view but has been conventionally shown in Fig. 10. Preferably the shaft 16 is positioned co-axially with any rotating shaft on the machine so that it will rotate and stop in accordance with the running and-stoppage of. the machine. Within quite wide limits, the speed of the shaft on the machine to which my transmitter shaft 76 is linked is of no importance.- It is essential, however, that when the machine is running, the commutator switch be capable of delivering a plurality of impulses to a register actuating magnet 22 within a signalling time interval whose duration is determined by the cam I1 (Fig. 4), that is to say, while the contacts 18 are caused to ground the conductor 19.

Bearings for the shaft 16 are provided by the left side-wall of the casing, also by a post 80. Mounted on the shaft 16 is a commutator which .comprises preferably a metallic member 8i insulated from the shaft by the sleeve 82 and having interconnected contact segments 88 interspaced with insulating material. Two brushes 84 bear against the cylindrical surface of the The metallic segments 83, being interconnected, are adapted by rotation to bridge the brushes 84 intermittently.

Usually it is desirable to transmit two impulses with every complete revolution of the shaft 56. This is accomplished when there are but two contact segments 83 opposing one another and when the brushes 84 bear against opposite sides of the cylindrical walls, as shown. impulses may, however, be transmitted at the rate of one per revolution of the shaft. 76, provided the two brushes bear against the same side of the commutator cylinder, the latter in this case, having only one metallic segment 83. If the speed of the shaft 16 is so slow that it is desired to multiply the number of impulses per revolution, then as many opposing metallic segments 83 as are suitable may be disposed peripherally of the commutator.

A manually operated shaft 85 having a control knob 86 is mountedco-axially with the shaft 16. This shaft carries and operates switching mechanism by which permutational signals may be set up for intermittent andperiodlc transmission, indicative of idle-time conditions with respect to the machine to be monitored. As will later be shown, these signals are transmittable only when a machine is stopped. They are directed through conductors b, c and d (Figs. 3 and 4) for controlling selector relays ill, 88 and 89, respectively, whereby the actuation of various timing registers (and annunciators, if desired) is effected.

In order to compare the actual number of revolutions of a machine with the elapsed running-time thereof for a given period, and thus to obtain the effective average speed of the machine, I have provided a revolution counter 98 the driven gear 9| of which meshes with a driving gear 92 mounted on the shaft 16. The units dial of the register 98 may, if desired, be so connected with the driven gear 9| that it will count in some multiple of single revolutions.

In the manually controlled switch shown in Fig. 7, there are two banks of contact-segments 93, each bank being mounted on an insulation disk 94. Interposed between the two banks is a pair of wipers 95, the form of which may preferably be somewhat as shown in Fig. 9. The fingers 96 are made of resilient material so that when selectively positioned by the rotation of the knob 86, any four adjacent segments (two in each bank) may be electrically interconnected. The wipers 95 are insulated from the shaft 85.

Fig, 3 shows diagrammatically one arrange ment of electrical connections to the segments 93. The pair of wipers 95 is shown in the home position where no idle time signal is transmittable because the machine to which the transmitter is connected is assumed to be running.

Since the knob 86 may be rotated to advance the wipers successively over different segments 93, it will be seen that a current when fed to the conductor 91 can be communicated simultaneously through the segments with which the wipers are in contact and back to the central station over any or all of the conductors b, c and d. In this manner permutational signals indicative of certain machine idleness causes may be transmitted and caused to actuate relays 81, 88 and 89 in any one of seven difierent combinations.

Any number of transmitting stations S may be served by a common wiring system comprising the conductors a, b, c and d, provided means are employed such that signalling currents may be transmitted unidirectionally through one transmitter at a time and .without the possibility of backing up" through other transmitters so as to confuse the signals. Accordingly I prefer to employ unidirectional devices at each transmitting station consisting of metal-oxide rectiflers 98. One of these rectifiers is placed in each of the output leads connecting with the common conductors a, b, c and 01. As shown in Fig. '7, each rectifier unit may consist of a number of seriesconnected plates r, and the end-plates of each unit may be provided with terminals 99. Insulation members 589 are, of course, inserted between the plates of electrically independent rectifiers. If desired, all rectifiers 98 may be supported by and insulated from one stud 508.

An indicating dial or drum l0! having periph eral designations I02 enables the operator to set the knob 86 intelligently for transmitting any desired signal. The dial and the switch are turned as a unit whenever the operator finds his machine to be in need of attention by someone other than the conductor a and to utilize conductors b, c and d for transmitting permutationally any one of seven idle-time signals. If a fourth conductor were to be provided for the permutational signals, then as many as fifteen such signals could be differentiated. A choice of only three permutations would be possible, however, if conductor d were to be omitted.

I have provided a clutch arrangement interconnecting the shafts l6 and 85 so that the manually operable switch may be automatically restored to a homing position whenever the machine is again started'after a period of idleness. The clutch comprises a dog member we mounted on a pivot pin A05 which in turn, is supported by the hub member I06, the latter being fastened to the end of the shaft 85. A notch It? is cut in the shaft 18 and is so positioned that as the shaft 16 rotates, the dog member I05 engages therein, being constantly urged against the shaft by the spring H0. Hence the machine, when it starts, rotates b'oth shafts 16 and 85 until the latter reaches a homing position. A detent I08 on the end of the dog member I06 then strikes an adjustable stud I09 in the bottom of the casing, thus disengaging the dog I04 from the notch fill. The shaft 16 then continues to rotate under controlof the machine as long as the machine operates,'whereas the shaft 85, bearing the idle-time signalling switch and dial fill, remains stationary until re-set. manually.

Only one of the stations S is enabled to trans-,

signals, the latter being returnd to the central station over any of the conductors a, b c and d. If desired, the wires 97 may be formed into one or more transmission cables F for at least part of their lengths.

In order to illustrate only one out of numerous practical applications of my invention, I have chosen for consideration the operating conditions in a weave room of a textile mill. Possibly the most prevalent causes of loom idleness are those which are designated in the following table, and in addition, the stoppages due to breakage of the warp threadsand filling threads. Since the weaver is responsible for piecing up the thread breaks, he cannot call for help as when other causes of idleness occur:

Manuel switch Relays Idle-time designations position m actuated or call for assistance 1 (Home) (Machine running). 2 b 87 Fixer.

hr! 87 89 Web twister. d 89 Cloth taker. cd 88 89 Warp out. bad 87 88 89 Repair material wait.

be 87 88 Filling out.

c S8 Smash.

As long as an idle-time switch remains set to a given signalling position, the periodic supply of current thereto from battery B through one of the segments Ill and the corresponding conductor 91 will permit signals to be transmitted to the relays8i, 88 and 8B as selected. These relays may be repeatedly energized and each time for only a portion of the timing cycle. Their common return circuit Il i is grounded in response to the operation ofthe cam H8 act- .ing upon the contacts H2. The peripheral contour of this cam is such that the circuit remains open while any one of the rotary switches R1. R2, and R3 is being stepped along, thus avoiding an objectionable arcing between the rotary switch wipers and their segments.

The circuits selectively established by the relays bl, B8 and 8t when working in different combinations are seven in number; hence current may be fed from battery B through the socalled Christmas tree arrangement of relay contact spring M5 to any of the conductors H6 and thence to an idle-time-register magnet such as H2: or 625. Each impulse impressed upon the actuating magnet l2 (Fig. 1) for such a register will release the same for a forward step indicative of an elapsed time interval of the same duration as exists between successive feedings of current to the particular transmitting station S under discussion.

The impulse applied to a magnet ,l? is of shorter duration than that for holding the relays 81, 88 and 89 energized. This is accom plished by making a common return circuit to ground from magnets i2 through normally close contacts ill of magnet 2t, through conductor 19, and through the cam-operated contacts I8. The cam contours are such that contacts 2 close before and open after contacts 18 close and open, respectively.

Since each idle-time registration is made within a unitary timing cycle (or single revolution of the cam-shaft 50) and since successive timing cycles are allotted each to a different station 5, it will be clear that any number bf different settings of the idle-time switches in respectively different signal boxes may be provided for to control the idle-time registers without mutual conflict.

Fig. 4 illustrates one solution of a problem encountered in the extension of my system so as to comprehend the monitoring of a large number of machines. I have found that my meter panels may conveniently be built toaccommodate multiples of ten machines and also multiples of twenty-four. The meter panels may be located centrally of any machine group which is to be monitored, in order that the distances covered by the transmission lines may be minimized.

The drawings show, merely for purposes of illustration, how I would employ three rotary switches R1, R2 and R3 each to serve the signaling requirements of ten stations S. The rotary switches shown have eleven segments in a bank. In one position no station S is connected, but when a wiper H8 (say of switch R1) steps onto the last segment H9 (its homing DOsition), its motor magnet M1 will be'disabled while the other rotary switches are caused in succession to rotate their wipers.

In the smaller installations these ll-position switches may be useful. If three such switches are installed in a single meterpanehthen the panel capacity will be such as toserve thirty stations S. However, rotary switches having} twenty-five segments in a bank arecommercially available. These are generally preferable to the switches shown in the drawings. schematically, the circuit and switching arrangements will be understood to be the same regardless .of the number of segments in a bank and regardless 7 of the number of rotary switches to be operated successively.

An impulsing device for actuating the motor .switches are preferably of the type that advance their wipers when the motor-magnet de-energizes. Hence the opening of the contacts I20 is synchronized with the'register driving motion as controlled by the cam 54. At the'same time contacts H2 and 18 will be open so that no relay action or register action can take place.

Each of the motor magnets M1, M2, and M3 is connected with the battery B and has an individual control circuit I26 leading to segments on the upper bank of an auxiliary switch R4. The positionoccupied by the wiper I23 determines which of the motor magnets M1, M2, or M: will be operative. In the drawings all wipers are viewed as though they rotated clockwise. The last segment to be reached is,. therefore, indicated at the bottom. The segment IIQ, instead of functioning to select a station S, will transmit current to one of the segments I21 on the lowest bank of the switch R4, thereby energizing its motor magnet M4. The return circuit passes through the wiper I28 of the middle contact bank. Some of the segments I28 of this bank are connected with the automatically grounded circuit breaker H9. The operation under this condition is, therefore, to advance the rotary switch R4 until the wiper I24 reaches one of the contacts I36, where it is momentarily arrested because these contacts are wired in multiple to the cam-operated grounding contacts E20. Rotary switch R4 then awaits the next periodic closing of the con- I tacts IZll, when it takes one further step in synchronism with an initial step made by one of the rotary switches R1, R2 or R3, depending upon which of the latter is in line for advancement.

Let it be assumed that the magnets M2 and M4. were thus energized and released, simultaneously. Rotary switch R; will now be positioned so that its wiper I25 is in contact with segment IZ'l" which has no immediate battery connection because current can only be fed to it (through segment H9) when the rotary switch R2 arrives at its homing position. This chain of operations enables the rotary switch R2 to make a complete excursion step-by-s-tep over its segments.

Referring again to Fig. 3, I have shown, merely for purposes of illustration, two registers 2 lg and 2h, which may be assigned to the function of accumulating machine running time by styles, and two associated registers l'g and Mn for indicating 100% machine time according to the same style-group. I have also shown two registers 2Ib and Me each of which is assigned to an operator group for the day shift and two similar registers Me and 2|: each assigned to an operator group for the night shift. The alternate connection of the day and night shift registers under control of viously determined standards for any period, I may provide two registers I Ix and My, one for the day shift and one for the night shift, merely as timing registers. That is to say, one of these registers will receive an impulse from the battery I3I with every cyclic impulse from the clock. The transfer of control from one register to the other at the change of shifts is a function of the previously described double-throw switch, in-

I cluding contacts I32 and I33. Contacts I32 are in circuit with the register-actuating magnet I 2x. Contacts I33 are in circuit with the register-actuating magnet I2 The impulses for advancing these registers are provided by the closing of the grounding contacts I8. Hence, the hours, say, from the starting up of the mill on Monday morning, up until any hour of operation of a day shift or night shift (exclusive of lunch hours) and on any day of the week may be indicated as a 100% elapsed time registration. With this 100% elapsed running time and elapsed idle time, as denoted by the other registers, may be compared.

If it is desired to make separate registrations of idle-time for the 'day shift and for the night shift, such can readily be accomplished. In this case, the return circuits from the day-shift idletime registers would be brought individually to the multiple contacts on one side of a doublethrow switch such as that shown in Fig. 3, while the return circuits from the night-shift registers would be oppositely disposed.

It is often times desirable that a record be kept of elapsed idle-time due to curtailment of the production schedules when there is lack of business for operating the plant on a 100% capacity basis. To meet this need I provide an idle-time register Ht, which will accumulate the lost machine hours in respect to machines to which no work is assigned. Ihis idle-time register diffcrs from the other idle time registers only in respect to the addition of a pair of circuit breaking contacts II? controlled from the armature of the register actuating magnet 2t. The purpose of the circuit breaking contacts is to disable all other idle-time registers when the idle ca pacity register is being operated. This arrangement is provided as a safeguard lest when machines are left unattended their manual switches should be carelessly or mischievously thrown into an operating position and thus destroy the accuracy of the idle-time registrations for other machines of the same group. It is to the machine operator's interest to obtain credit for the maximum percentage of running-time and to set the knob 86 to an idle time designation only when assistance is called for. Hence, for machines that are under an operator's control, there is practically no danger that false idle-time signals-would be transmitted.

The control circuit for the idle-capacity timing register Hz includes a multiple arrange ment of back contacts I3 1, each associated with a tip contact 72 of one of the jacks 6%, as shown in Fig. 4. With respect to any one of these jacks current is fed to the tip contact i?- from battery B; through a wiper I35 and segment It belonging to one of the rotary switches R1, R2, and R3. During a complete cycle covering the testing of all the machines to be monitored, each tip contact .12 of the jacks receives one impulse. If a plug is inserted in the jack this impulse operates accumulation all registrations of a 100% timing register (such as H or 11) dethe jack, contact will be'made between the two springs 12 and 134, whereby the impulse is directed through conductor 136 to the actuating magnet [2r for the idle capacity timing register Hi. The return circuit Hi from the magnet lZt leads to the cam-operated grounding contacts H2 which are closed simultaneously for this magnet and for the relays 81, 88 and'89. From this it will be seen that at each position occupied by one of the wipers 135 of the rotary switches a certain jack will be selected. If a plug Til-has been inserted therein for timing and tabulating the machine operation by job groups, the 100% time registration will be made, but if no plug is inserted in the jack, the idle capacity register will be actuated. Thetotal hours for the assigned machinesas registered on the various,

100% registers H llh, etc. plus the total of idlehours as registered on the idle capacity register Ht will, therefore, give a grand total of machine hours for the machines that are monitored d ing any given period.

Referring now to Fig. 5, I show a modification of my invention. There are many instances where productive machines are provided with automatic devices, commonly called "stop-motion.f If anything goes wrong with the automatic mechanisms of the machine itself or in case of defects in thematerial that is being processed, it is the function of the stop-motion" device to stop the machine as quickly as possible, thereby to prevent damage either to the machine as quickly as possible, thereby to prevent damage either to the machine or to the product. An automatic loom presents perhaps as good an example as is needed to make this point clear. Present day looms are usually equippedwith warp stop-motions. and filling stop-motion. As an example of a warp stop-motion, reference is made to U. S. Patent No. 1,265,112 to Regan, dated May '7, 1918. A filling stop-motlon is shown in U. S. Patent No. 1,353,824 to Finn, dated September 28, I920. Stop-motions for other types of machines are well known. As an example thereof, the stop-motion device for a knitting machine may be mentioned as shown in U. S. Patent No. 1,342,245 to Ames, dated June 1. 1920. It,is typical of these stop-motion devices that when anything goes wrong with the functioning of the machine or with the feeding of the material in process, a mechanical movement takes place such as to throw the shipper-handle or driving control member into position for cutting off the motive power and for stopping the machine.

Thus. if a warp-thread breaks, a certain designated mechanism is brought into play which causes the loom to stop. The same thing occurs but in a diiferent manner if the threadtrailed by the shuttle happens to break. In such instances it may be desirable to register the time of machine idleness from the moment the machine stops until it is again put into operation by the operator. Furthermore, it is desirable to know which is the chief offender in pulling down the efficiency,-the breakage of warp or the breakage of filling.

In order to meet the conditions just described, I have shown a modification 0f my invention in which certain portions of Fig. 3 and Fig. 4 are either duplicated or the structural parts thereof are indicated without more than an abbreviated representation in Fig. 5. Like parts have been given corresponding reference numerals and characters. I provide signalling circuits, one of which may be closed by the operation of a switch 131 which-may be understood to'bconnected to one of the stop motions 237 on the machine, the other circuit being similarly closed by a switch 138 connected with another of the stop motions 2-38 on the machine. Current is fed through the cable to these switches intermittently in ac cordance with the successive selection of difierent signalling stations S, as previously described in connection with Figs. 3- and 4. In the drawings, block diagrams have been used to represent the stop-motion devices because, as is well known in the art, such stop-motion devices vary a great deal in their structural arrangements, and applicant 'does not need to be limited to any particular structural features of these devices so long as he utilizes any convenient mechanical motion thereof for actuating the switches 13? and 033;

It is obvious that contacts of a switching arrangement may be closed by any convenient relative movement between different parts of a mechanism such as a stop-motion. All that is necessary is to mount one of the contact elements on a stationary support and preferably insulated therefrom and to mount the other contact element through which the circuit is to be closed on a portion of the mechanism which moves in response to the occurrence of a given condition. Thus, in the case of the operation of a stopmotion on a loom there are certain elements which are displaced by breakage of threads in the material under process. When mounting one of a pair of contact springs on such a displaceable element this contact spring can be caused to engage with a stationarily mounted. contact spring thereby to' close any circuit such as shown leading to one of the switches I37 or 138. i

As shown in the diagram, the individual conductor 91' feeds directly to certain of the contact elements 93 in the signal box S. A branch 91" feedsthrough a dash-pot relay 139 to a contact 93' with which the brush 95 is engaged when in register-actuating magnets 2|, as hereinbefore described. When, however, the machine stops and, forexample, the switch I3? is closed by its stop-motion 231, an impulse will be transmitted through the contact segments 93' and 93s., the switch I37 and conductor d, thereby actuating relay 89 to select a circuit I40 which leads to actuating magnet 12k for a register I I k designating idle-time due to this particular kind of stoppage. A similar registration of idle-time due to the operation of a different stop motion 238 may be made as when the switch 138 is closed, thereby feeding impulses through the contact segments '93'93b, and thence through said switch to the conductor c which actuates relay 88 for selection of the actuating magnet lZm of register Hm. In this manner two of the seven available permutations of signals are transmittable when the brush 95 occupies the home position,

leaving only five other positions of the manually adjustable switch available for designating machine idleness due to other causes. These five permutations are, however, selectable at will in the manner hereinbefore described for operating the permutation relays 8T, 88 and 89.

The dash-pot relay 139, when it is'actuated, serves, if desired, to close a signalling circuit independent of all other circuits shown. in the diagram, which circuit may be useful in giving 7! a warning to the operator that this particular machine has stopped. Such a warning may be audible as when the bell IQI or other'audible signalling device is sounded; or the signal may be visible, as when the lamp I42 is lit. In either case the operator who may at the moment be tending some other of the machines of his set, is given due warning that this particular machine is in need of his attention. The warning signal circuit derives its energy from the generator or other source I 43 and the duration of the signal may be made as long as desired by adjusting the return-stroke of the relay armature I44. Such adjustment, as is well known, may readily be made by controlling a vent (not shown) in dash pot of relay I39.

In the operation ofmy system it may, for example, be desirable to go the rounds of the various machines to be monitored by feeding current to each transmitting station, once every 2 minutes. The dash-pot relay may be adjusted to maintain a closed circuit condition of its contacts I45 for a considerable fraction of 2 minutes, and certainly for a longer time interval than that represented by one only of the many closings of contacts H2 (Fig. 4) during a period of 2 minutes. The circuit through the dash-pot relay operates periodically whenever either of the stop motion switches I31I38 is closed. When, however, the brush 95 of the permutation switch is manually set, then, even though the brush 95 has been the moved only one step and is still in contact with the segment 93' in circuit with the dash-pot relay I39, the' latter will nevertheless be short circuited by the branch conductor 91'.

Another feature of the embodiment shown in Fig. 5 provides that when .any particular code signal is transmitted such as one designating fixer call, a distribution and analysis of signals can be provided so as to assign responsibility for idle time to the proper individual. Assuming, for example, that the "fixer call signal is represented by an impulse transmitted over conductor b to relay 81, then the operation of this relay will feed current from battery B to a wiper I46 of the rotary switch R5. This wiper, it will be understood, is caused to contact successively with segments I 41-of rotary switch R5. These seg ments connect individually with certain plug-in connector jacks I48. Three such jacks are shown (by way of example) connected in parallel to each conductor M9. Thus any group of machines to be cared for by an individual fixer may be selectively linked to a common feeder circuit I50 for one of the dash-pot relays 85B and the actuating magnet I2 for an associated register II lu. The cam operated contact 18 serves to complete this circuit periodically in the same manner as shown in Fig. 4. Each of the dash-pot relays l5I operates a contact spring 852 for closing a circuit from the source of current 553 to a particular annunciator which, in this case, has been indicated as-a lamp I55, although, of course, a visible or audible annunciator of any type may be used In accordance with this arrangement the proper individual is given a warning signal that he is needed for the repair of some one of the machines in his particular section. Until this man is able to put such machine in repair and get it running again the idle time will count against him in accordance with the actuation of the timing register I In.

In the embodiment shown in Fig. 5, the secing with one of the machines.

the machine operators efliciency. In this case, as has heretofore been shown, the idle-time may be the result of machine stoppage for either of two reasons, according to which particular one of the stop motion switches I 31-I38 happens to have closed its circuit for transmitting an idle-time signal. Considering a loom, for example, if it stops due to warp thread breakage then the warp stop motion 231 will close the switch I31, whereat a signal is transmitted over conductor d, the effect of which is to actuate relay 89 so as to close a local circuit at the register panel from the battery B to register actuating magnet '21:, thence to the brush I55 on the second level of the rotary switch R5 and through one of the segments I55 by which the signal is properly distributed to a jack I51 corresponding with the loom from whose signaling box S the signal originated.

A forked two-wire cork-and-plug connector (14 in Fig. 4 and 14' in Fig. 5) may here be used for connecting any number of jacks I51 with a register, jack. Two registers, one an idle-time register II- and the other a running-time register 2I may then be made responsive to signals from any of the looms in a weavers 'set. Additional pairs of registers II2I may likewise be served by signals directed to other sets of jacks I51, according to the assignment of looms to each weaver and according to a corresponding concentration of signalling channels from selected jacks I51 through other forked cords to jacks for respective pairs of said registers.

On referring back to the description of how a signal may be initiated by the closing of switch I31 when a warp stop-motion 231 operates on a loom, it will be clear that any other stop-motion (for example, one that is controlled by a filling break) f may operate the switch I38 thereby to transmit an impulse through channel 0 to relay 88. The operation of this relay selects register actuating magnet I2m for actuation. The return circuit for this magnet is common to that of I21; already described. It puts different idle-time magnets II in series with either of the magnets I 2m or I21; according to the selectivity of wiper I55 on'rotary switch R5. Hence the idle-time due to warp andfilling thread breakage may be ascribed to each weavers loom set and for all the looms it may be analyzed on registers II}: and m to determine the losses due to warp breakage relative to filling breakage.

The contact bank comprising segments I58 of the rotary SWitChRs is useful for feeding current from the battery B successively to the tip contacts 12 of different jacks, each correspond- When machines are assigned to any particularjob (there being a number of jobs running simultaneously), a 100% registration of machine hours may be obtained on separate timing registers II, each being representative of a selected group of machines. The twin conductor cord 14" terminates in a plug ItI which may be inserted in the jack 69. This cord comprises a circuit leading to a register 2i for tabulating-running-time under a job-classification. The sleeve connection of the plug IBI connects with the body of the jack 59, which in turn is connected to one of the front contacts I58 of the relay I55. The other two front contacts of the relay I 55 connect respectively with jacks I51 and ISO. When no plug IBI is inserted in the jack 65, then contacts 12 and I34 are closed for the purpose of transmitting signals to register 92: (Fig. 3) indicative of machine time unassigned.

It will be seen that a three-fold tabulation of running time may be had when relay its is actuated. This relay is actuated by current from the battery B through a segment H62 on the lowermost bank of the rotary switch R5 when grounding contacts iii? close. in shunt with a feeder circuit to a corresponding transmitting station 8. If runningtime signals are transmitted, they are fed back through conductor a to three movable contacts of relay its. One set of registers it will receive running-time impulses as through the sleeve connection of the plug use for designating the operators runningtime, a second distribution of the impulse in parallel'with the first will be distributable through the sleeve connection of plug it! for designating running-time by job, as heretofore explained. Whenever it is desired that a machine should be monitored individually, the running-time thereof may be registered by plugging into the jack E65 of a single conductor cordand-plug I 66, thereby making connection with an individual register 2i.

Since the arrangement shown in Fig. 5 requires as many relays I59 as there are machines to be monitored, it is perhaps 'a matter of economy to provide a rotary switch having more than four banks of segments, and thus to eliminate the need for relays. Such a modification may, therefore, be preferred, as shown in Fig. 6, in which a rotary switch is provided having five main banks of segments. Two of these banks are provided with split segments insulated from one another, although their wipers are electrically connected. Such an arrangement may be provided in commercially available apparatus and has the advantage that current may be fed to the individual signalling devices attached to the different machines while synchronously distributing the signalling impulses from their respective stations S in accordance with a number of different classifications. To illustrate the possibilities in this direction Fig. 6 shows an arrangement of wipers and segments as follows: Wiper it connects battery through segments I68 with the different feeder circuits 9? leading respectively to stations S. Wiper 55 also feeds current from the battery through segments GM to the 100% running-time registers for accumulating such tirneby jobs. Running time signals from stations S are distributed by wiper I58 through segments W9 and till to registers for designating the running time by jobs, and by individual machines, if desired. Wiper Ill similarly distributes the same signals to registers for tabulation of the running-time of the machines according to I operator's groups. Finally there are two upper contact banks, m

and H6 the wipers H3 and N5 of which correspond with wipers i56 and MS respectively as shown in Fig. 5. In one case the operator's idle-.

time may be accumulated on registers individual to each operator; in the other'case the fixers idle-time may be correspondingly registered in The relay 859 is characterized principally by the substitution of one bank of contact segments instead of two for composing the permutational elements of an idle time signal. Three t a n cl e m disposed brushes H8 are mounted on the rotatable brush holder W9, which is carried by and insulated from the shaft 85. Current is impulsively fed by conductor 91 to the brush collector ring i80.

signals may be duplicated at different settings of the switch. The seven possible combinations of selection of the three conductors are made available as shown.

Recapitulation g In the foregoing detail description of .my invention, its application to the monitoring of looms has been referred to by way of lllustration. Applications to other types of machinery, and even to operations that are largely manual in character, are too numerous to mention. In general, however, it may be seen that the utility of my invention is greatest where there is considerable complexity in the co-ordinatlon of dif ferent operations as performed by different productive units, or groups of units. If the movement of material in process from one stage to another is properly controlled, then it does not pile up excessively at different points. nor is there a lack of material where machinery and operators are available to put it through the next succeeding step of the process. It is only by taking note of the departures from a predetermined production schedule that a supervisor can take action to improve the efiiciency and to speed up the flow of work.

In the register panel an ever-changing picture of progress throughout the plant is available. At the beginning of each week readings of all the registers may be transcribed or photographed. Further readings may be obtained as often as desired for noting the elapsed runningtime in comparison with the 100% machine hours, and for noting the elapsed idle-time due to various causes.

In some instances it may be desirable to employ registers II and 2! of the so-called re-set" type. To do this requires no change in the structure or operation of my invention, since my improved register-actuating device may be geared, belted or linked to any suitable counter, as is well understood by those' skilled in the art.

Furthermore, it would be no departure, from the spirit and scope of my invention to actuate a pen-recording chart instrument of any of the types well known and heretofore considerably used for denoting the times and frequency of occurrence of any event such as a period of machine idleness. I have shown such an instrument in Fig. 12, wherein the principles of my 7 invention are deemed to be well exemplified. It

is apparent, however, that the magnets IE or 22 might well be utilized for individually controlling each of a plurality of pen-arms of a recording instrument.

The few timing registers shown in Fig. 3 are taught.

but typical of those which would'normally be used in great numbers in a large industrial plant. For payroll records there should be a separate register to accumulate machine running time to be credited to each machine operator. If the pay were to be figured on the basis of this runnlng time, rather than on subsequently compiled estimates of quantities produced, the operators would be assured of a more equitable compensation for their eiforts. The effects upon their wages of variations. in machine speeds would also be removed, thereby rendering the labor conditions more satisfactory.

For production control there should be register assigned to each kind of productor job order. For time-study work there should be a certain number of registers 2| available to follow the operation of individual machines as occasion may require. This has been mentioned in the foregoing description of Fig. 5. Finally, for supervisory control of the retarding factors, a suflicient number of idle-time registers II should be employed so that, depending upon the nature of the work, the predominant factors of lost time may be quantitatively analyzed.

Such, in general, is of the essence of this invention. It is to be understood, however, that modifications may be made without departing from the spirit and scope of what is herein I do not intend, therefore, to be limited except insofar as is necessitated by the prior art and by the scope of the appended claims.

I claim:

1. Apparatus for producing at a central station a condensed tabular registration of elapsed running time and idle time in respect to a plurality of productive units, comprising means under control of said productive units for transmitting impulses indicative of elapsed running time, additional means associated with the first said means and at times manually operable for transmitting impulses indicative of idleness of said productive units for any oia plurality of assignable causes, a timing device, means including a plurality of timing registers, under thejoint control of said timing device and of the first said means for tabularly registering the elapsed running time by groups of said units according to a predetermined classification of said units and again by different groups according to a different classification of said units, means including dill a second plurality of timing registers under the joint control of said timing device and of said additional impulsing means for tabularly registering the elapsed idle time of said units according to the causes for such idleness, and means including preadjustable circuit connections from the impulse and the signal transmitting means to said timing registers for determining each group of productive units in respect to which elapsed time registrations are to be made.

h 2. Apparatus in accordance with claim '1 in which said additional signalling means comprises a manually settable switch associated with each productive unit, the switch being adapted to be set to a signalling position only when the productive unit is stopped, and means for restoring said switch to a non-signalling condition upon the starting-up of the productive unit with which said switch is operatively associated.

3. In combination with a productive machine having a plurality of stop-motions, each stopmotion being operative in response to the rise of a particular cause of shut-down, monitoring apparatus comprising means for transmitting signals, each signal being so characterized as to denote the cause of shut-down, means for period ically repeating said signal for the duration of the shut-down, and means including a plurality of timing registers for tabularly accumulating in response to said signals the elapsed time in respect to each classof machine idleness as determined by the particular stop-motion that is operated in each instance.

4. In combination with a plurality of productive machines having stop-motion devices, a monitoring system comprising circuit-closing devices attached to said stop-motion devices and operative therewith, a timing mechanism and means including a plurality of timing registers operative under the joint control of said timing mechanism and of said circuit-closing devices when a machine is idle for accumulating the idle time thereof in'synoptic arrangement according to each of a plurality of assignable causes of machine stoppage, and selective means for causing each of said registers to be connected in common to the circuit closing devices on a plurality of productive machines, a separate register being provided for each class of stop-motion devices on said machines, thereby to designate the time lost'on account of stoppage for diiferent causes.

5. The invention set forth in claim 4 in which the monitoring system comprises further means including selective circuits and a manually adjustable switch adjacent each machine and additional timing registers operative under the joint control of said timing mechanism, said selective circuit means and said manually adjustable switch, said registers being adapted to synoptically accumulate time lost on account of inability of the operator to again start his machine due to one cause or another beyond his immediate control, as indicated by the setting of said manually adjustable switch, a register being provided for each of a plurality of the usual causes of that nature.

-6. In a work-meter system applicable to the measurement of running time of a plurality of productive machines, a first set of timing registers, selective means for rendering each register operable according to a desired group of machines to each of which it is cyclically connected,

at least one other set of timing registers adapted to function alternatively like the first set, and time-controlled means for transferring the connections from one to another of said sets upon shifting from one to another crew of operators of'said machines.

7. In combination with a machine whose periods of operation and of idleness are to be tabularly registered, means under control of the machine when it is running for periodically and intermittently transmitting impulses indicative of running time intervals, a register operable under control of said impulses to register accumulations of running-time in respect to said machine, means under control of an operator of said machine when it is idle for intermittently tit transmitting impulses over a predetermined pertime accumulations being separately registered according to the respective causes therefor.

8. In a tabulative telemetering system, a plurality of productive machines the elapsed running time and the elapsed idle time conditions of which are to be registered, a signalling device operatively connected with each machine and comprising both machine operated and manually settable switches, a timing mechanism, an elapsed time tabulator comprising a plurality of selectively operable registers under the joint control of said timing mechanism and of the signalling devices, a transmission system connecting said signalling devices with the registers of said tabulator and having a conductor individual to each signalling device and a plurality of conductors common to all of the signalling devices, means under control of said timing mechanism for periodically energizing the individual conductors successively and in rotation, and means including unidirectional devices electrically connecting said signalling devices with said common conductors for preventing the transposition of signals as impressed upon said common con.- ductors.

9. In a tabulative telemetering system in combination with a plurality of productive units the working and idle conditions of which are to be registered, a signal transmitting device under separate control of each said unit while it is running and adapted to be manually adjusted only when the unit is idle, time controlled means including rotary switches for periodically and successively supplying; current to each said transmitting device, means including relays permutationally controlled by said transmitting devices for interpreting the selective function of certain of the signals initiated by said signal transmitting devices, tabulative means including a plurality of elapsed timeregisters selectable in part by said rotary switches and in part by said relays and thereby caused to respond to the control of said signal transmitting devices for accumulating a plurality of synoptic totals of elapsed time in respect to the working-and idle conditions of said productive units, and means including circuits selectively connectable between said signal transmitting devices, said rotary switches, saidrelays and said registers for predetermining the response of said registers to said signals according to any desired grouping of said units into operators sets, or by kinds of product to which said units are assigned, and according to a plurality of different causes to any one of which the said idle conditions may be assigned.

10. In a timing system, in combination with a plurality of machines the working conditions of which are to be tabulated, means operatively connected with each said machine for monitoring said conditions, a plurality of elapsed-time registers selectively operable under control of said monitoring means, and means for so determining the selection of registers to be operated in said machines as classified according to a second analytical basis.

11. A timing system in accordance with claim and having further means for disabling the monitoring means in respect to any of the machines to be excluded from the predetermined groups due to lack of orders or absence of the operator, and means including an additional elapsed time register for accumulating machine hours in respect to the machines so excluded.

12. In a timing system, a plurality of produc tive units, the idle conditions of which are to be timed and tabulated, a plurality of elapsed-time registers, means manually adjustable upon the stoppage of any one of said productive units for monitoring said conditions and for transmitting impulses during idleness periods in respect to any of said units in response to which said reg isters are actuated, an elapsed-time register assigned to the function of accumulating time lost by any of said productive units for lackof assignment of work to be performed thereon, manually adjustable means for rendering the last said register operable and means operating in conjunction with the last said register-when it is actuated for preventing the actuation of any of the first said registers.

13. In a work-meter system applicable to the group analysis and measurement of running time of a plurality of productive machines, means operatively connected with each said machine for transmitting impulses indicative of a running condition, time controlled switching means for picking up said impulses in periodic succession from diiferent individual machines, a plurality of impulse-controlled timing-registers, including a running-time register and a full-time register for each group of machines, and manually adjustable means flrstly for predetermining the particular machines to be included in each group, secondly for causing said impulses to be distributed to a different running-time register for each group, and thirdly for causing a companionate full-time register to accumulate a 106 17 totalof machine-hours for its group.

14. In combination with a plurality of machineshaving signalling means operatively connected therewith, a plurality of elapsed-runningtime registers, a timing mechanism, registeractuating devices under the joint control of said timing mechanism and of said signalling means, switching means operative under control of said timing mechanism for establishing electrical circuits periodically and successively through different ones of said signalling means and also simultaneously in parallel branches through a selected plurality of said actuating devices, and

means including volitionally adjustable connections between said switching means and said actuating devices whereby tabulated totals of actual running-time in respect to selected groups of said machines are accumulated on said registers, the. group selected through one of said parallel branches being according to one basis of classification of said machines and the group simultaneously selected through another of the parallel branches being according to an independent basis of classification.

15. The invention set forth in claim 14 in com-v bination with an elapsed-running time register, an actuating device therefor, means including suitable circuit connections between said actuating device and the signalling means for causing said register to accumulate a grand total of running machine hours for a given period in respect to all of the machines, and registering means for simultaneously accumulating the elapsed millhours during the same period. 16. In combination with a plurality of machines whose periods of operation and of idleness are to be tabularly registered, means under acct/ms control of each machine when it is running for periodically and intermittently transmitting signals indicative of running-time intervals in respect to that particular machine, a plurality of elapsed time registers, each responsive to such of said signals as relate to the running-time of a predetermined group of said machines, manually settable means associated with each machine and operable only when the machine is stopped for periodically and intermitmntly transmitting idle-time signals, and a plurality of idle-time registers each adapted to respond to such of said idle-time signals as relate to machine idleness assignable to a specific cause as denoted by the adjustment of said settable means.

17. In a timing system, a plurality of productive units the idle conditions of which are to be synoptically registered, means including switches vancement of said registers, and means operative under control of said monitoring means for causing said registers to be selectively actuated in accordance with the idle time synoptically accumulated under different idleness-cause captions.

18. A system in accordance with claim 17 and having means including a stop-motion device operable by the production unit when it is to be automatically stopped for closing the switch of said monitoring means, said stop-motion device 'being operable upon restarting said productive unit to open said switch.

19. A system in accordance with claim 17 including in said monitoring means a. manually adjustable switch for' designating certain predetermined causes of idleness and at least one stop-motion device connected to said unit and having associated therewith a switch automatically operable in response to the stopping of the productive unit for establishing a certain predetermined permutational selection of said circuits thereby to designate the stoppa e of said unit under control of said stop-motion device.

20. In combination with a productive machine, monitoring apparatus comprising switching means for transmitting any one of a plurality of different signals each signal being characterized to indicate a particular idle-time condition in respect to said machine, a plurality of signalling channels selectively operable by said switching means, means under control of currents directed into said channels for registering said idle-time conditions, and further means under control of the machine while it is running for preventing the transmission of signals by said switching meaps.

21. In a tabulative telemetering system, a plurality of productive machines, the elapsed running time and the elapsed idle-time conditions of which are to be registered, a signalling device operatively connected with each machine and comprising both machine operated and manually settable switches, a timing mechanism, means for causing said signalling device to transmit impulses under control or" said timing mechanism, a plurality of signalling channels and an elapsed time tabulator comprising a plurality of selectively operable registers under control of impulses transmitted through said signalling channels, and means operable by any one of said machines when it stops for initiating the transmission of impulses to certain of said registers thereby to accumulate totals of machine idleness time on said registers selectively in dependence upon the cause of such idleness, said registers being receptive of impulses from different groups of said productive machines so as to obtain condensed tabular registrations of elapsed time in respect to the idleness of said machines.

22. The combination of an operable machine, a plurality of stop-motions each adapted to stop the machine upon the occurrence of a specific type of failure of said machine to properly function, a plurality of registers, timed impulse responsive means for advancing said registers, means operable under control of any one of said stop-motions, when it is actuated, for selecting an appropriate one of said registers to be advanced, and means for rendering said impulse responsive means effective only so long as the machine remains idle.

23. The combination of a productive machine having a stop-motion adapted to stop the machine, a register, intermittently operable register controlling means, and means dependent upon the stoppage of the machine by the stop motion for enabling said controlling means to advance the register.

24. The combination of a. loom, a filling stopmotion and a warp stop-motion each adapted to stop the loom, a pair of registers, intermittently operable register controlling means, means dependent upon the actuation of the filling stopmotion for causing said controlling means to advance one of said registers, means dependent upon the actuation of the warp stop-motion for causing the controlling means to advance the other of said registers, a timing device for contlnuing the operation of said controlling means, and means dependent'upon the re-starting o! the loom for terminating the intermittent advaucement of either of said registers, thereby to measure the 'duration of loom idleness due to stoppage by the respective stop-motions.

RALPH W. BUMSTEAD. 

